photon detection with simultaneous electron reconstruction in high pressure xenon diego gonzalez...
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Photon detection with simultaneous electron reconstruction in High
Pressure Xenon
Diego Gonzalez Diaz (Univ. Zaragoza and CERN)
RD51 Academia-Industry Matching Event
Special Workshop on Photon Detection with
MPGDs
11/06/2015
main characteristics of gas for X- and γ-ray detection
• Competitive energy resolution at the scale of 0.4-1.2%√1/MeV (light readout) and 1-4.5%√1/MeV (charge readout).
• Active medium is easily exchangeable!. Large choice of Z: He(Z=2)->Xe(Z=54).
• Relative ease of photo-electron reconstruction, multi-site(Compton) or pair production.
main advantages of Xenon
• High density (more compact detector).
• Easily detectable scintillation at 170nm (Xenon works also as wave-length shifter!).
εγ =1.25MeV
response to γ-tracks in a typical gaseous detector (TPC)
Ne
40keV 80keV
From NIST
He, Ne, Xe
300keV
some figures of merit depending mainly on the gas filling
εγ=140keV (10cm drift, 10bar)
Compton camera
X-ray detector
from C. Azevedo and J. Veloso
Two main detector technologies for X and γ-ray detection
charge readoutlight readout
1. Classical charge-readout TPC
e-γ
t
2D information fromreadout pixelization
typical x-ray event
zi=vdtiwidth σt,i
time ti
εi =integral
3D information frompulse shape
3D-positioning from diffusion of ionization-cloud (?)
field cagereadout plane
drift region
the readout: micro-pattern hole-amplification structure(‘microbulk MicroMegas’)
copper
copper
kapton
88x [μm]
z [μ
m]
50 μm
5 μm100 μm
40 μm100μm
100Mio holes/m2
Manufacturable in 30cm x 30cm (MM) and 1m x 1m (GEM)
(also standard MM or GEM depending on the conditions)
drift and drift-to-readout transition readout
How does it work?, in a nut-shell
final performance in a real-size system with charge-readout
X-ray
Active volume: 38cm x 700cm2
P=10bar
Xe/TMA (99/1)
Operation time: 100 live days(nearly no sign of deterioration)
2.4% √1/MeV
4.5% √1/MeV
2. Optical TPC
e-γ
2D information fromreadout pixelization
3D-positioning from primary scintillation (S1)
3D information frompulse shape
PMT tubes
SiPMs
Xenon is an excellent wave-lengthshifter for other noble gases!
yield: S1=17000 γ/MeV
primary scintillation emission spectrum
How does it work?, in a nut-shell
time dependence
very fast at high pressure
secondary scintillation yield
Poisson
~ 400 γ/e-/cm/bar
yield
fluctuations
0.97% √1/MeV 1.15% √1/MeV
22Na (511keV)
137Cs (662keV)
cosmic ray
final performance in a real-size system with light-readout
Active volume: 30cm x 150cm2
P=10bar
pure Xe (99/1)
Operation time: several months
typical cases of interest for γ-reconstruction (photon angle and/or polarization)
(borrowed from HARPO TPC (Argon))
Photo-electron at 511-30keVand displaced X-ray (30keV)
Multi-Compton eventat 511 keV
Photo-electron at 1.275 MeV
Pair production at 18.00 MeV
Main present application is indeed fundamental research (ββ0-decay)
2-blob ββ0 event at Qββ
background eventat Qββ
already under installation at LSC
γ-rays are the background… not the signal!!: golden signature is ‘1blob vs 2blob’
blob-blob correlation (22Na, 1.274 MeV, bck-like)
blob-blob correlation (208Tl, 1.6 MeV, signal-like)
MCsignal
enhanced blob-identification capabilities in a low-diffusion mixture (Xenon-TMA)
Bragg peaks
ongoing ideas
• Look for a convenient ‘Penning-Fluorescent’ wavelength-shifting mixture. Xe-TMA behaves as desired in many aspects, but S1 yields go down by 1/20. Penning probability is also modest, and no strong reduction of the Fano factor.
• Identify electron-cooling gases (low diffusion) with modest quenching rates. From existing data and simulations, Xe-CH4 would work.
• Use magnetic field to bend the electrons and increase the identification capabilities.
• Very active research on large volume (and high pressure) Xenon TPCs.
• For operation under pure (or nearly pure) noble gas fillings, they can be replaced and adapted to a new energy range, while the optical characteristics remain nearly the same upon small Xenon additions.
• MPGD charge readouts are inferior in terms of energy resolution, but can compete due to the larger simplicity and easiness of segmentation.
• NEXT is trying to make a breakthrough in ββ0 detection… not necessarily on gamma detection, but who knows?.
conclusions and outlook
appendix
JINST 9(2014)P03010, JINST 9(2014)C04015
38cm
30cm
details in:
1kg of Xe at 10bar